FPGA device for image classification

ABSTRACT

Image processing systems can include one or more cameras configured to obtain image data, one or more memory devices configured to store a classification model that classifies image features within the image data as including or not including detected objects, and a field programmable gate array (FPGA) device coupled to the one or more cameras. The FPGA device is configured to implement one or more image processing pipelines for image transformation and object detection. The one or more image processing pipelines can generate a multi-scale image pyramid of multiple image samples having different scaling factors, identify and aggregate features within one or more of the multiple image samples having different scaling factors, access the classification model, provide the features as input to the classification model, and receive an output indicative of objects detected within the image data.

FIELD

The present disclosure relates generally to detecting objects ofinterest. More particularly, the present disclosure relates to detectingand classifying objects that are proximate to an autonomous vehicle inpart by using a field programmable gate array (FPGA)-based imageprocessor.

BACKGROUND

An autonomous vehicle is a vehicle that is capable of sensing itsenvironment and navigating with little to no human input. In particular,an autonomous vehicle can observe its surrounding environment using avariety of sensors and can attempt to comprehend the environment byperforming various processing techniques on data collected by thesensors. Given knowledge of its surrounding environment, the autonomousvehicle can identify an appropriate motion path through such surroundingenvironment.

Thus, a key objective associated with an autonomous vehicle is theability to perceive objects (e.g., vehicles, pedestrians, cyclists) thatare proximate to the autonomous vehicle and, further, to determineclassifications of such objects as well as their locations. The abilityto accurately and precisely detect and characterize objects of interestis fundamental to enabling the autonomous vehicle to generate anappropriate motion plan through its surrounding environment.

SUMMARY

Aspects and advantages of embodiments of the present disclosure will beset forth in part in the following description, or can be learned fromthe description, or can be learned through practice of the embodiments.

One example aspect of the present disclosure is directed to an imageprocessing system. The image processing system includes one or morecameras configured to obtain image data. The image processing systemalso includes one or more memory devices configured to store aclassification model that classifies image features within the imagedata as including or not including detected objects. The imageprocessing system also includes a field programmable gate array (FPGA)device coupled to the one or more cameras. The FPGA device is configuredto implement one or more image processing pipelines for imagetransformation and object detection. The one or more image processingpipelines include a plurality of logic blocks and interconnectorsprogrammed to: generate a multi-scale image pyramid of multiple imagesamples having different scaling factors; identify and aggregatefeatures within one or more of the multiple image samples havingdifferent scaling factors; access the classification model stored in theone or more memory devices; provide the features within the one or moreof the multiple image samples as input to the classification model; andproduce an output indicative of objects detected within the image data.

Another example aspect of the present disclosure is directed to avehicle control system. The vehicle control system includes one or morecameras configured to obtain image data within an environment proximateto a vehicle. The vehicle control system also includes a fieldprogrammable gate array (FPGA) device coupled to the one or more imagesensors, the FPGA device configured to implement one or more imageprocessing pipelines for image transformation and object detection. Theone or more image processing pipelines include a plurality of logicblocks and interconnectors programmed to: generate a multi-scale imagepyramid of multiple image samples having different scaling factors;identify and aggregate features within one or more of the multiple imagesamples having different scaling factors; and to detect objects ofinterest within the multiple image samples based at least in part on thefeatures. The vehicle control system also includes one or more computingdevices configured to receive an output from the FPGA device and tofurther characterize the objects of interest.

Another example aspect of the present disclosure is directed to a methodof detecting objects of interest. The method includes receiving, by oneor more programmable circuit devices, image data from one or morecameras. The method also includes generating, by the one or moreprogrammable circuit devices, a multi-scale image pyramid of multipleimage samples having different scaling factors. The method also includesanalyzing, by the one or more programmable circuit devices, successiveimage patches within each of the multiple image samples using a slidingwindow of fixed size. The method also includes pooling, by the one ormore programmable circuit devices, image patches associated by likefeatures into image regions within each of the multiple image samples.The method also includes accessing, by the one or more programmablecircuit devices, a classification model that classifies image regions asincluding or not including detected objects. The method also includesproviding, by the one or more programmable circuit devices, the imageregions as input to the classification model. The method also includesreceiving, by the one or more programmable circuit devices, an output ofthe classification model corresponding to detected objects of interestwithin the image data.

Other aspects of the present disclosure are directed to various systems(e.g., computing systems, vehicle systems, image processing systems),apparatuses (e.g., vehicles, computing devices, image processors),non-transitory computer-readable media, user interfaces, and electronicdevices.

These and other features, aspects, and advantages of various embodimentsof the present disclosure will become better understood with referenceto the following description and appended claims. The accompanyingdrawings, which are incorporated in and constitute a part of thisspecification, illustrate example embodiments of the present disclosureand, together with the description, serve to explain the relatedprinciples.

BRIEF DESCRIPTION OF THE DRAWINGS

Detailed discussion of embodiments directed to one of ordinary skill inthe art is set forth in the specification, which makes reference to theappended figures, in which:

FIG. 1 depicts a block diagram of an example programmable circuit device(e.g., FPGA device) according to example embodiments of the presentdisclosure;

FIG. 2 depicts a block diagram of an example vehicle control systemaccording to example embodiments of the present disclosure;

FIG. 3 depicts example aspects of an object detection pipeline accordingto example embodiments of the present disclosure;

FIG. 4 depicts a block diagram of an example camera system according toexample embodiments of the present disclosure;

FIG. 5 depicts a block diagram of an example computing system accordingto example embodiments of the present disclosure;

FIG. 6 depicts an example multi-scale image pyramid according to exampleembodiments of the present disclosure;

FIG. 7 depicts a first example aspect of sliding window image analysisaccording to example embodiments of the present disclosure;

FIG. 8 depicts a second example aspect of sliding window image analysisaccording to example embodiments of the present disclosure;

FIG. 9 depicts a third example aspect of sliding window image analysisaccording to example embodiments of the present disclosure;

FIG. 10 depicts a fourth example aspect of sliding window image analysisaccording to example embodiments of the present disclosure; and

FIG. 11 depicts a flow diagram of an example method for detectingobjects of interest according to example embodiments of the presentdisclosure.

DETAILED DESCRIPTION

Reference now will be made in detail to embodiments, one or moreexample(s) of which are illustrated in the drawings. Each example isprovided by way of explanation of the embodiments, not limitation of thepresent disclosure. In fact, it will be apparent to those skilled in theart that various modifications and variations can be made to theembodiments without departing from the scope or spirit of the presentdisclosure. For instance, features illustrated or described as part ofone embodiment can be used with another embodiment to yield a stillfurther embodiment. Thus, it is intended that aspects of the presentdisclosure cover such modifications and variations.

Example aspects of the present disclosure are generally directed toimage classification technology for vehicle applications. Classificationof images in vehicle applications, especially for purposes of objectdetection, can require a substantial amount of processing power andanalytical precision to yield effective and accurate results. Thedisclosed image classification techniques can provide substantialimprovements to that end by utilizing one or more cameras in conjunctionwith a field programmable gate array (FPGA) device. Image classificationby the FPGA device can generally include a one or more processingportions directed to image transformation and/or object detection. Imagetransformation can include generating a multi-scale image pyramid ofimage samples characterized by multi-parameter integer-basedrepresentations that can be more easily handled by an FPGA device andthat can result in more accurate object detection. Image processing withan FPGA device corresponding to a single programmable chip coupled tothe one or more cameras helps to greatly improve the processing speedfor feature extraction, object detection and/or other image processingaspects as disclosed herein. Utilization of an FPGA device providessystem functionality to perform a vast number of image processingoperations in parallel including multi-scale image analysis as opposedto the linear functionality afforded by conventional processor-basedcomputing devices that implement one set of instructions at a time.

More particularly, an image processing system in accordance with exampleembodiments of the disclosed technology can include one or more camerasconfigured to obtain image data. In some examples, the cameras canrespectively include one or more initial filters, a lens selectivelyconfigured to focus on one or more regions of interest, a shutterselectively controlled between open and closed positions in accordancewith one or more exposure protocols (e.g., a global shutter exposureprotocol), a color filter array, an image sensor, and the like. Eachimage sensor can include a charge-coupled device (CCD) sensor and/or acomplementary metal-oxide-semiconductor (CMOS) sensor, although otherimage sensors can also be employed. Each camera can include an array ofimage sensor elements configured to detect incoming light providedincident to a surface of the camera and convert the received amount oflight into a corresponding electric signal. The electric signal capturedat each image sensor element can provide image data at a plurality ofpixels, each pixel corresponding to a corresponding image sensor elementwithin a camera.

An image processing system in accordance with the disclosed technologycan more particularly include one or more programmable circuit devicessuch as a field programmable gate array (FPGA) device. In some examples,the one or more cameras can be coupled directly to the FPGA device viaone or more image interface protocols (e.g., Low-Voltage DifferentialSignaling (LVDS)). The FPGA device or other programmable circuit devicecan include a plurality of logic blocks and interconnectors that can beprogrammed into specific configurations for implementing variousoperations. In some implementations, such various operations can includeone or more image processing pipelines. In some examples, such variousoperations can include a first image processing pipeline for imagetransformation and a second image processing pipeline for objectdetection. The image transformation and object detection pipelines canresult in generation and classification of multiple different imagevariations simultaneously because the pipelines are implemented using anFPGA device as opposed to conventional processor-based computingdevices. Although some FPGA device examples are described herein asincluding separate first and second image processing pipelines, itshould be appreciated that other implementations could include allfeatures in a single image processing pipeline or features split acrossdifferent combinations of pipelines than those explicitly depicted anddiscussed.

In some example implementations, the first image processing pipeline forimage transformation can more particularly include a plurality of logicblocks and interconnectors programmed to implement one or moretransformation techniques including De-Bayering, gamma correction,rectification, anti-aliasing, etc.

In some implementations, the first image processing pipeline for imagetransformation can more particularly include a plurality of logic blocksand interconnectors designed to convert intermediate stages of imagedata from a floating point representation to fixed point integer-basedrepresentation. In some examples, converting image data to aninteger-based representation can include resizing image data size valuescharacterized by a first number of bits to image data size valuescharacterized by a second number of bits. In some implementations, thesecond number of bits can be different and smaller than the first numberof bits. In some implementations, each bit in the first number of bitscan be analyzed using a technique such as a histogram to determine whichbits in the first number of bits is more important to the image data.The histogram or other technique can then be used to help determinewhich bits in the second number of bits are kept from the first numberof bits and which bits or discarded or otherwise modified.

In some implementations, the first image processing pipeline for imagetransformation can more particularly include a plurality of logic blocksand interconnectors programmed to convert image data from arepresentation having multiple color components into a greyscalerepresentation. In some examples, such image transformation can moreparticularly correspond to converting image data into a multi-parameter(HSG) representation corresponding to values for an image hue (H)parameter, an image saturation (S) parameter, and an image greyscale (G)parameter.

In some implementations, the first image processing pipeline for imagetransformation can more particularly include a plurality of logic blocksand interconnectors programmed to resize the image data obtained by theone or more cameras. In some implementations, for example, imageresizing can include downsampling the image data into a multi-scaleimage pyramid. The multi-scale image pyramid can include image data thatis translated into multiple image samples having different scalingfactors. In some implementations, the multi-scale image pyramid can becharacterized by a number of octaves (e.g., powers of two) and a numberof scales per octave. Some or all of the image samples generated by thefirst image processing pipeline can then be provided as input to thesecond image processing pipeline for object detection.

In some implementations, for example, the second image processingpipeline for object detection can more particularly include a pluralityof logic blocks and interconnectors programmed to identify and aggregatefeatures within one or more of the multiple image samples within amulti-scale image pyramid. The second image processing pipeline can alsoaccess a classification model, for example a classification model thatis stored in one or more memory devices (e.g., DRAM) accessible by theprogrammable circuit device (e.g., FPGA). The classification model canbe configured to classify image portions and/or image features asincluding or not including detected objects.

The features identified and aggregated from the image samples can beprovided as input to the classification model. An output then can bereceived from the classification model corresponding to objects detectedwithin the image data (e.g., vehicles, cyclists, pedestrians, trafficcontrol devices, etc.) In some examples, the output from theclassification model can include an indication of whether image featuresinclude or do not include detected objects. For features that includedetected objects, the classification model can include a classificationfor a detected object as one or more objects from a predetermined set ofobjects. In some examples, the classification model can also output aprobability score associated with the classification, the probabilityscore being indicative of a probability or likelihood of accuracy forthe classification. In some implementations, the classification modelcan include a decision tree classifier. In some implementations, theclassification model is a machine-learned model such as but not limitedto a model trained as a neural network, a support-vector machine (SVM)or other machine learning process.

In some implementations, for example, the second image processingpipeline for object detection can more particularly include a pluralityof logic blocks and interconnectors programmed to identify and aggregateedge portions within some or all of the image samples in the multi-scaleimage pyramid. In some examples, the object detection pipeline isfurther configured to implement an angle binning algorithm thatdetermines an angle classification for each of the identified edgeportions and assigns each edge portion to one of a plurality ofdifferent bins based at least in part on the angle classificationdetermined for that edge portion. A histogram, such as but not limitedto a histogram of oriented gradients, descriptive of the plurality ofdifferent bins can be generated. In some examples, the plurality ofdifferent bins can be defined to have different sizes based on theamount of image data in each image sample such that bin sizes aresmaller for image samples having a greater amount of image data.

In some implementations, for example, the second image processingpipeline for object detection can more particularly include a pluralityof logic blocks and interconnectors programmed to generate one or morechannel images from the image data, each channel image corresponding toa feature map that maps a patch of one or more input pixels from theimage data to an output pixel within the channel image.

In some implementations, for example, the second image processingpipeline for object detection can more particularly include a pluralityof logic blocks and interconnectors programmed to determine a slidingwindow of fixed size, analyze successive image patches within each ofthe multiple image samples using the sliding window of fixed size, andidentify objects of interest within the successive image patches. Insome examples, image patches can be pooled into image regions associatedby like features within each of the multiple image samples. Pooled imageregions can be identified by boxes or other bounding shapes identifiedwithin an image. In some examples, the pooled image regions can beprovided as an input to the classification model, which then generatesan output corresponding to detected objects of interest within the imageregions.

In some examples, one or more outputs from the classification modeland/or some or all of the image data including one or more imagevariations can be provided as output data to one or more computingdevices in a vehicle control system. The vehicle control system cancontrol an operational parameter of a vehicle (e.g., speed, direction,etc.) in response to detection of at least one object of interest in theimage data. In this manner, a vehicle can turn and/or stop uponconditions being detected within the image data, including but notlimited to the approach of another vehicle, a pedestrian crossing theroad, a red traffic light being detected at an intersection, and thelike. The one or more computing devices can include a perception system,a prediction system, and a motion planning system that cooperate toperceive the surrounding environment of a vehicle and determine a motionplan for controlling the motion of the vehicle accordingly.

In some examples, a vehicle control system configured to analyze imagedata and/or classification outputs from a disclosed image processingsystem can be provided as an integrated component in an autonomousvehicle. The autonomous vehicle can be configured to operate in one ormore modes, for example, a fully autonomous operational mode and/or asemi-autonomous operational mode. A fully autonomous (e.g.,self-driving) operational mode can be one in which the autonomousvehicle can provide driving and navigational operation with minimaland/or no interaction from a human driver present in the vehicle. Asemi-autonomous (e.g., driver-assisted) operational mode can be one inwhich the autonomous vehicle operates with some interaction from a humandriver present in the vehicle.

In particular, in some implementations, the perception system canreceive image data and/or image classification information from thedisclosed image processing system as well as sensor data from one ormore additional sensors. Additional sensors can include, for example, aranging system such as but not limited to a Light Detection and Ranging(LIDAR) system and/or a Radio Detection and Ranging (RADAR) system. Theimage data, image classification information and sensor data can becollectively analyzed to determine the location (e.g., inthree-dimensional space relative to the autonomous vehicle) of pointsthat correspond to objects within the surrounding environment of theautonomous vehicle (e.g., at one or more times).

The perception system can identify one or more objects that areproximate to the autonomous vehicle based on some or all of the imagedata, image classification information and sensor data. In particular,in some implementations, the perception system can determine, for eachobject, state data that describes a current state of such object. Asexamples, the state data for each object can describe an estimate of theobject's: current location (also referred to as position); current speed(also referred to as velocity); current acceleration; current heading;current orientation; size/footprint (e.g., as represented by a boundingshape such as a bounding polygon or polyhedron); class ofcharacterization (e.g., vehicle versus pedestrian versus bicycle versusother); yaw rate; and/or other state information. In someimplementations, the perception system can determine state data for eachobject over a number of iterations. In particular, the perception systemcan update the state data for each object at each iteration. Thus, theperception system can detect and track objects (e.g., vehicles,bicycles, pedestrians, etc.) that are proximate to the autonomousvehicle over time.

The prediction system can receive the state data from the perceptionsystem and predict one or more future locations for each object based onsuch state data. For example, the prediction system can predict whereeach object will be located within the next 5 seconds, 10 seconds, 20seconds, etc. As one example, an object can be predicted to adhere toits current trajectory according to its current speed. As anotherexample, other, more sophisticated prediction techniques or modeling canbe used.

The motion planning system can determine a motion plan for theautonomous vehicle based at least in part on predicted one or morefuture locations for the object and/or the state data for the objectprovided by the perception system. Stated differently, given informationabout the current locations of objects and/or predicted future locationsof proximate objects, the motion planning system can determine a motionplan for the autonomous vehicle that best navigates the autonomousvehicle along the determined travel route relative to the objects atsuch locations.

As one example, in some implementations, the motion planning system candetermine a cost function for each of one or more candidate motion plansfor the autonomous vehicle based at least in part on the currentlocations and/or predicted future locations of the objects. For example,the cost function can describe a cost (e.g., over time) of adhering to aparticular candidate motion plan. For example, the cost described by acost function can increase when the autonomous vehicle approaches impactwith another object and/or deviates from a preferred pathway (e.g., apredetermined travel route).

Thus, given information about the current locations and/or predictedfuture locations of objects, the motion planning system can determine acost of adhering to a particular candidate pathway. The motion planningsystem can select or determine a motion plan for the autonomous vehiclebased at least in part on the cost function(s). For example, the motionplan that minimizes the cost function can be selected or otherwisedetermined. The motion planning system then can provide the selectedmotion plan to a vehicle controller that controls one or more vehiclecontrols (e.g., actuators or other devices that control gas flow,steering, braking, etc.) to execute the selected motion plan.

The systems and methods described herein may provide a number oftechnical effects and benefits. For instance, image processing systemsand methods that implement image transformation and object detectionusing an FPGA device (or ASIC device) coupled to one or more cameras cangenerally provide faster image processing speed and reduce potentialprocessing latencies. Image processing with an FPGA device correspondingto a single programmable chip coupled to the one or more cameras helpsto greatly improve the processing speed for feature extraction, objectdetection and/or other image processing aspects as disclosed herein.High-throughput on-chip memories and data pipelining associated withFPGA device implementation allows for image processing to occur inparallel to images being read out from an image sensor, thus making thedisclosed image processing systems and methods uniquely capable ofreal-time or near real-time object detection at fast enough speeds toadvantageously affect the behavior of an autonomous vehicle.

More particularly, utilization of an FPGA device can provide systemfunctionality to perform a vast number of image processing operations(e.g., on the order of thousands of processing operations or more) inparallel including multi-scale image analysis as opposed to the linearfunctionality afforded by conventional processor-based computing devicesthat implement one set of instructions at a time. In someimplementations, the number of image frames per second analyzed by anFPGA-based image processor can be on the order of 5-10 times more than aconventional processor-based image processor. The improved imageprocessing capacity afforded by coupling an FPGA device with one or morecameras can help achieve a level of image processing functionality thatwas otherwise unachievable with micro-processor functionality inconventional computing devices.

The systems and methods described herein may provide an additionaltechnical effect and benefit of improved accuracy in object detection byproviding techniques for actual implementation of higher quality andmore comprehensive algorithms for object detection. For example, bytransforming initially obtained image data into multiple differentvariations (e.g., different image samples in a multi-scale image pyramidand/or multiple different channel images generated from original imagedata), parallel processing on the image variations can provide morecomprehensive image analysis. The likelihood of detecting objects withinimage regions or other image portions in an effective and timely mannercan thus be significantly enhanced.

The systems and methods described herein may provide an additionaltechnical effect and benefit of improved accuracy in object detection byproviding image transformation techniques implemented by anFPGA-processing pipeline that yield image enhancements that ultimatelyimproves object detection. For instance, combined use of one or moretransformation techniques including gamma correction, rectification,and/or anti-aliasing can help result in the generation of a multi-scaleimage pyramid whose image data characteristics are better maintainedacross the different scales of image samples. Conversion of image datafrom a representation having multiple color components into a greyscalerepresentation (e.g., a multi-parameter representation corresponding to(HSG) values for an image hue (H) parameter, an image saturation (S)parameter, and an image greyscale (G) parameter, can result in an imageform better suited for object detection in vehicle applications. Stillfurther transformation techniques such as Sobel filtering can help toimprove the identification of certain image features (e.g., detection ofedge portions) within the different image samples or channel images. Thespecific types of image transformation techniques implemented using FPGAtechnology combine to provide enhanced image classification.

The disclosed improvements to image processing can be particularlyadvantageous for use in conjunction with vehicle computing systems forautonomous vehicles. Because vehicle computing systems for autonomousvehicles are tasked with repeatedly detecting and analyzing objects inimage data for localization and classification of objects of interestincluding other vehicles, cyclists, pedestrians, traffic changes, andthe like, and then determining necessary responses to such objects ofinterest, enhanced image processing can lead to faster and more accurateobject detection and characterization. Improved object detection andclassification can have a direct effect on the provision of safer andsmoother automated control of vehicle systems and improved overallperformance of autonomous vehicles.

The systems and methods described herein may also provide resultingimprovements to computing technology tasked with image classificationand object detection. Improvements in the speed and accuracy of objectdetection can directly improve operational speed and reduce processingrequirements for vehicle computing systems, ultimately resulting in moreefficient vehicle control. By providing an image processing system thatincludes an FPGA device (or ASIC device) configured to implement imagetransformation and object detection, valuable computing resources withina vehicle control system that would have otherwise been needed for suchtasks can be reserved for other tasks such as object prediction, routedetermination, autonomous vehicle control, and the like.

With reference to the figures, example embodiments of the presentdisclosure will be discussed in further detail. FIG. 1 depicts a blockdiagram of an example programmable circuit device (e.g., FPGA device100) according to example embodiments of the disclosed technology. Imagedata 102, such as captured by an image sensor within one or more camerascan be provided as input to the FPGA device 100. Data link(s) forproviding image data 102 can operate using different signalingprotocols, including but not limited to a Low-Voltage DifferentialSignaling (LVDS) protocol, a lower voltage sub-LVDS protocol, a CameraSerial Interface (CSI) protocol using D-PHY and/or M-PHY physicallayers, or other suitable protocols and interface layers. The FPGAdevice 100 can be provided as an integral part of a camera or a separatecomponent interfaced with one or more cameras. Additional description ofa camera for obtaining image data 102 is provided in FIG. 6.

FPGA device 100 can include a plurality of logic blocks andinterconnectors that can be programmed into specific configurations forimplementing various operations. In some implementations, such variousoperations can include one or more image processing pipelines. In someexamples, such various operations can include a first image processingpipeline 110 for image transformation and a second image processingpipeline 120 for object detection. The first and second image processingpipelines 110, 120 can result in generation and classification ofmultiple different image variations simultaneously because the pipelinesare implemented using FPGA device 100 as opposed to conventionalprocessor-based computing devices. Although FPGA device 100 is describedherein as including various components as part of a respective firstimage processing pipeline 110 and second image processing pipeline 120,it should be appreciated that an FPGA device 100 can alternativelyimplement a combination of components from such pipelines into a singlepipeline or multiple different pipelines (e.g., two or more in differentcombinations than described herein).

In some example implementations, the first image processing pipeline 110for image transformation can more particularly include a plurality oflogic blocks and interconnectors programmed to implement one or moretransformation components including a bit conversion component 111, ade-Bayering component 112, a gamma correction component 113, a colorspace conversion component 114, rectification component 115, ananti-aliasing component 116, and a resizing component 117. Althoughmultiple components are described as part of the first image processingpipeline 110, it should be appreciated that embodiments of the disclosedtechnology need not include all such components. As such, some of thecomponents within first image processing pipeline 110 can be optional toaccommodate selective customization of image transformation features.

Referring more particularly to the bit conversion component 111, aplurality of logic blocks and interconnectors within FPGA device 100 canbe programmed to convert intermediate stages of the image data 102 froma floating point representation to fixed point integer-basedrepresentation. In some examples, converting intermediate stages of theimage data 102 to an integer-based representation can include resizingimage data values characterized by a first number of bits to image datavalues characterized by a second number of bits. In someimplementations, the second number of bits can be different and smallerthan the first number of bits. In some implementations, each bit in thefirst number of bits can be analyzed using a technique such as ahistogram to determine which bits in the first number of bits is moreimportant to the image data (e.g., which bits convey image data that ismore likely to include objects of interest within an image). Thehistogram or other technique can then be used to help determine whichbits in the second number of bits are kept from the first number of bitsand which bits or discarded or otherwise modified.

Referring more particularly to the de-Bayering component 112, aplurality of logic blocks and interconnectors within FPGA device 100 canbe programmed to convert image data that has been received through acolor filter array into a data format that includes multiple colorcomponents per pixel. For example, an array of image sensor elements(e.g., corresponding to respective pixels) can be positioned relative toa color filter array having one or more different color filter elements.The particular arrangement of color filter elements can vary. Forexample, some color filter elements can be red, blue, green, and/orclear/white. De-Bayering component 112 can be configured to receivelight of a particular color at each image sensor element, and thenreconstruct a full color image by interpolating values for multiplecolor components at each image sensor element or pixel within the imagedata.

Referring more particularly to the gamma correction component 113, aplurality of logic blocks and interconnectors within FPGA device 100 canbe programmed to implement a nonlinear contrast adjustment to image data102. Gamma correction component 113 can be configured to ultimatelycontrol the brightness within image data in a manner that providesenhanced distinction among captured image features to facilitate betterobject detection.

Referring more particularly to the color space conversion component 114,a plurality of logic blocks and interconnectors within FPGA device 100can be programmed to convert image data 102 from a representation havingmultiple color components into a greyscale representation. In someexamples, such image transformation can more particularly correspond toconverting image data into a multi-parameter (HSG) representationcorresponding to values for an image hue (H) parameter, an imagesaturation (S) parameter, and an image greyscale (G) parameter. Theimage hue (H) parameter can be representative of the light property forimage data that characterizes how color is classified as one of multiplecolor parameters (e.g., red, green, blue, white, yellow, etc.) relativeto one or more respective pure reference values for each color parameterin the color spectrum. The image saturation (S) parameter can berepresentative of the light property for image data that characterizesthe intensity of color within the image relative to brightness. Theimage greyscale (G) parameter can be representative of the lightproperty for image data that characterizes the intensity of monochromelight for each pixel within an image. The use of multi-parameter HSGrepresentations for image data 102 provides an enhanced image dataformat that has proven to be beneficial for image-based object detectionapplications. These benefits are achieved in part by the type of imageinformation captured using the hue, saturation and greyscale parameters.

Referring more particularly to the rectification component 115, aplurality of logic blocks and interconnectors within FPGA device 100 canbe programmed to implement an alignment transformation that shifts imagedata 102 to positions within a reference system (e.g., another image, amap of area surrounding a vehicle, and/or a reference grid of pointsdefining three-dimensional space surrounding a vehicle).

Referring more particularly to the anti-aliasing component 116, aplurality of logic blocks and interconnectors within FPGA device 100 canbe programmed to implement an image filter that splits respectiveoptical points (e.g., image data pixels) into a cluster of points. Thisanti-aliasing component 116 can help ensure a proper sampling of imagedata 102 before the image data is resized into multiple samples viaresizing component 117.

Referring more particularly to the resizing component 117, a pluralityof logic blocks and interconnectors within FPGA device 100 can beprogrammed to resize the image data 102 obtained by the one or morecameras. In some implementations, for example, image resizing atresizing component 117 can include downsampling the image data 102 intoa multi-scale image pyramid. The multi-scale image pyramid can includeimage data that is translated into multiple image samples 118 havingdifferent scaling factors. In some implementations, the multi-scaleimage pyramid can be characterized by a number of octaves (e.g., powersof two) and a number of scales per octave.

Referring still to FIG. 1, some or all of the image samples 118generated by the first image processing pipeline 110 can then beprovided as input to the second image processing pipeline 120 for objectdetection. In some example implementations, the second image processingpipeline 120 for image transformation can more particularly include aplurality of logic blocks and interconnectors programmed to implementone or more components including a Sobel filter component 121, an anglebinning component 122, a convolution component 123, a pooling component124, and a classification component 125. Although multiple componentsare described as part of the second image processing pipeline 120, itshould be appreciated that embodiments of the disclosed technology neednot include all such components. As such, some of the components withinsecond image processing pipeline 120 can be optional to accommodateselective customization of image transformation features.

Referring more particularly to the Sobel filter component 121, aplurality of logic blocks and interconnectors within FPGA device 100 canbe programmed to identify and enhance directional changes in the lightintensity between adjacent pixels or other designated portions of eachimage sample 118. For each image point, these directional changes can berepresented by a horizontal derivative representing changes in imageintensity in the horizontal direction and a vertical derivativerepresenting changes in image intensity in the vertical direction. Insome implementations, the output of Sobel filter component 121 is animage sample 118 having enhanced edges resulting from a modification ofthe image data within each image sample 118 based at least in part onthe determined horizontal and vertical derivatives at each image point.

Referring more particularly to the angle binning component 122, aplurality of logic blocks and interconnectors within FPGA device 100 canbe programmed to implement an angle binning algorithm that characterizesthe directional changes in image intensity determined within the Sobelfilter component 121. In some implementations, angle binning component122 is configured to determine a spatial gradient magnitude for imagepoints within each image sample based at least in part on the horizontaland vertical derivatives determined by Sobel filter component 121. Insome implementations, angle binning component 122 is further configuredto characterize the spatial gradient magnitudes on a per point/pixelbasis within each image sample. In other implementations, spatialgradient measurements can be characterized on a per feature basis withineach sample, where each feature is part of a channel image feature mapthat maps a patch of one or more input pixels from image data to anoutput pixel within the channel image feature map.

More particularly, in some examples, the angle binning component 122 isconfigured to determine an angle classification for each of theidentified image components (e.g., pixels, features and/or edgeportions) and assigns each image component to one of a plurality ofdifferent bins based at least in part on the angle classificationdetermined for that image component. A histogram, such as but notlimited to a histogram of oriented gradients, descriptive of theplurality of different bins within angle binning component 122 can begenerated. In some examples, the plurality of different bins can bedefined to have different sizes based on the amount of image data ineach image component such that bin sizes are smaller for imagecomponents having a greater amount of image data.

Referring more particularly to the convolution component 123, aplurality of logic blocks and interconnectors within FPGA device 100 canbe programmed to filter image samples 118 using one or more convolutionmatrices to sharpen and enhance edges within each image sample. In someimplementations, convolution component utilizes a plurality ofconvolution matrices, for example on the order of between about 4matrices and about 20 matrices, each matrix having N×N integer values,with the matrix size value N being between about 3 and 6.

Referring more particularly to the pooling component 124, a plurality oflogic blocks and interconnectors within FPGA device 100 can beprogrammed to determine a sliding window of fixed size, analyzesuccessive image patches within each of the multiple image samples 118using the sliding window of fixed size, and identify objects of interestwithin the successive image patches. In some examples, image patches canbe pooled into image regions associated by like features within each ofthe multiple image samples. Pooled image regions can be identified byboxes or other bounding shapes identified within an image. In someexamples, the pooled image regions can be provided as an input to theclassification component 125, which then generates an outputcorresponding to detected objects of interest within the image regions.

Referring more particularly to the classification component 125, theFPGA device 100 can be configured to access a classification model 130that is configured to classify image portions and/or image features asincluding or not including detected objects. In some implementations,classification model 130 can be stored in one or more memory devices(e.g., DRAM) accessible by FPGA device 100. In some implementations, theclassification model 130 can include a decision tree classifier or othersupervised learning model. In some implementations, the classificationmodel 130 can be a machine-learned model such as but not limited to amodel trained as a neural network, a support-vector machine (SVM) orother machine learning process.

More particularly, the classification component 125 can be configured toprovide the image regions from pooling component 124 as input to theclassification model 130. A classification output 132 then can bereceived from the classification model 130 corresponding to objectsdetected within the image data. In some examples, the classificationoutput 132 from classification model 130 can include an indication ofwhether image regions include or do not include one or more objects. Forimage regions that include detected objects, the classification output132 from classification model 130 can include a classification for adetected object as one or more classes from a predetermined set (e.g.,vehicles, cyclists, pedestrians, traffic control devices, etc.). In someexamples, the classification output 132 from classification model 130can also include a probability score associated with the classification.For example, the probability score can be indicative of a probability orlikelihood of accuracy for the classification (e.g., a likelihood thatan object is or is not detected, or a likelihood that a classificationfor an object (e.g., as a pedestrian, bicycle, vehicle, etc.) iscorrect.

FIG. 2 depicts a block diagram of an example vehicle control systemaccording to example embodiments of the present disclosure. Moreparticularly, a vehicle control system 200 can be included within orotherwise associated with an autonomous vehicle 202. The autonomousvehicle 202 is capable of sensing its environment and navigating withouthuman input. The autonomous vehicle 202 can be a ground-based autonomousvehicle (e.g., car, truck, bus, etc.), an air-based autonomous vehicle(e.g., airplane, drone, helicopter, or other aircraft), or other typesof vehicles (e.g., watercraft). The autonomous vehicle 202 can beconfigured to operate in one or more modes, for example, a fullyautonomous operational mode and/or a semi-autonomous operational mode. Afully autonomous (e.g., self-driving) operational mode can be one inwhich the autonomous vehicle can provide driving and navigationaloperation with minimal and/or no interaction from a human driver presentin the vehicle. A semi-autonomous (e.g., driver-assisted) operationalmode can be one in which the autonomous vehicle operates with someinteraction from a human driver present in the vehicle.

The autonomous vehicle 202 can include one or more sensors 204, avehicle computing system 206, and one or more vehicle controls 208. Thevehicle computing system 206 can include one or more computing devicesconfigured to assist in controlling the autonomous vehicle 202. Inparticular, the vehicle computing system 206 can receive sensor datafrom the one or more sensors 204, attempt to comprehend the surroundingenvironment by performing various processing techniques on datacollected by the sensors 204, and generate an appropriate motion paththrough such surrounding environment. The vehicle computing system 206can control the one or more vehicle controls 208 to operate theautonomous vehicle 202 according to the motion path.

As illustrated in FIG. 2, in some embodiments, the vehicle computingsystem 206 can include a perception system 210, a prediction system 212,and a motion planning system 214 that cooperate to perceive thesurrounding environment of the autonomous vehicle 202 and determine amotion plan for controlling the motion of the autonomous vehicle 202accordingly.

In particular, in some implementations, the perception system 210 canreceive sensor data from the one or more sensors 204 that are coupled toor otherwise included within the autonomous vehicle 202. As examples,the one or more sensors 204 can include a Light Detection and Ranging(LIDAR) system 222, a Radio Detection and Ranging (RADAR) system 224,one or more cameras 226 (e.g., visible spectrum cameras, infraredcameras, etc.), and/or other sensors. The sensor data can includeinformation that describes the location of objects within thesurrounding environment of the autonomous vehicle 202.

As one example, for LIDAR system 222, the sensor data can include thelocation (e.g., in three-dimensional space relative to the LIDAR system222) of a number of points that correspond to objects that havereflected a ranging laser. For example, LIDAR system 222 can measuredistances by measuring the Time of Flight (TOF) that it takes a shortlaser pulse to travel from the sensor to an object and back, calculatingthe distance from the known speed of light.

As another example, for RADAR system 224, the sensor data can includethe location (e.g., in three-dimensional space relative to RADAR system224) of a number of points that correspond to objects that havereflected a ranging radio wave. For example, radio waves (pulsed orcontinuous) transmitted by the RADAR system 224 can reflect off anobject and return to a receiver of the RADAR system 224, givinginformation about the object's location and speed. Thus, RADAR system224 can provide useful information about the current speed of an object.

As yet another example, for one or more cameras 226, various processingtechniques can be performed to identify the location (e.g., inthree-dimensional space relative to the one or more cameras 226) of anumber of points that correspond to objects that are depicted in imagerycaptured by the one or more cameras 226.

Thus, the one or more sensors 204 can be used to collect sensor datathat includes information that describes the location (e.g., inthree-dimensional space relative to the autonomous vehicle 202) ofpoints that correspond to objects within the surrounding environment ofthe autonomous vehicle 202.

In addition to the sensor data, the perception system 210 can retrieveor otherwise obtain map data 218 that provides detailed informationabout the surrounding environment of the autonomous vehicle 202. The mapdata 218 can provide information regarding: the identity and location ofdifferent travelways (e.g., roadways), road segments, buildings, orother items or objects (e.g., lampposts, crosswalks, curbing, etc.); thelocation and directions of traffic lanes (e.g., the location anddirection of a parking lane, a turning lane, a bicycle lane, or otherlanes within a particular roadway or other travelway); traffic controldata (e.g., the location and instructions of signage, traffic lights, orother traffic control devices); and/or any other map data that providesinformation that assists the vehicle computing system 206 incomprehending and perceiving its surrounding environment and itsrelationship thereto.

The perception system 210 can identify one or more objects that areproximate to the autonomous vehicle 202 based on sensor data receivedfrom the one or more sensors 204 and/or the map data 218. In particular,in some implementations, the perception system 210 can determine, foreach object, state data that describes a current state of such object.As examples, the state data for each object can describe an estimate ofthe object's: current location (also referred to as position); currentspeed (also referred to as velocity); current acceleration; currentheading; current orientation; size/footprint (e.g., as represented by abounding shape such as a bounding polygon or polyhedron); class (e.g.,vehicle versus pedestrian versus bicycle versus other); yaw rate; and/orother state information.

In some implementations, the perception system 210 can determine statedata for each object over a number of iterations. In particular, theperception system 210 can update the state data for each object at eachiteration. Thus, the perception system 210 can detect and track objects(e.g., vehicles, pedestrians, bicycles, and the like) that are proximateto the autonomous vehicle 202 over time.

The prediction system 212 can receive the state data from the perceptionsystem 210 and predict one or more future locations for each objectbased on such state data. For example, the prediction system 212 canpredict where each object will be located within the next 5 seconds, 10seconds, 20 seconds, etc. As one example, an object can be predicted toadhere to its current trajectory according to its current speed. Asanother example, other, more sophisticated prediction techniques ormodeling can be used.

The motion planning system 214 can determine a motion plan for theautonomous vehicle 202 based at least in part on the predicted one ormore future locations for the object provided by the prediction system212 and/or the state data for the object provided by the perceptionsystem 210. Stated differently, given information about the currentlocations of objects and/or predicted future locations of proximateobjects, the motion planning system 214 can determine a motion plan forthe autonomous vehicle 202 that best navigates the autonomous vehicle202 relative to the objects at such locations.

As one example, in some implementations, the motion planning system 214can determine a cost function for each of one or more candidate motionplans for the autonomous vehicle 202 based at least in part on thecurrent locations and/or predicted future locations of the objects. Forexample, the cost function can describe a cost (e.g., over time) ofadhering to a particular candidate motion plan. For example, the costdescribed by a cost function can increase when the autonomous vehicle202 approaches a possible impact with another object and/or deviatesfrom a preferred pathway (e.g., a preapproved pathway).

Thus, given information about the current locations and/or predictedfuture locations of objects, the motion planning system 214 candetermine a cost of adhering to a particular candidate pathway. Themotion planning system 214 can select or determine a motion plan for theautonomous vehicle 202 based at least in part on the cost function(s).For example, the candidate motion plan that minimizes the cost functioncan be selected or otherwise determined. The motion planning system 214can provide the selected motion plan to a vehicle controller 216 thatcontrols one or more vehicle controls 208 (e.g., actuators or otherdevices that control gas flow, acceleration, steering, braking, etc.) toexecute the selected motion plan.

Each of the perception system 210, the prediction system 212, the motionplanning system 214, and the vehicle controller 216 can include computerlogic utilized to provide desired functionality. In someimplementations, each of the perception system 210, the predictionsystem 212, the motion planning system 214, and the vehicle controller216 can be implemented in hardware, firmware, and/or softwarecontrolling a general purpose processor. For example, in someimplementations, each of the perception system 210, the predictionsystem 212, the motion planning system 214, and the vehicle controller216 includes program files stored on a storage device, loaded into amemory, and executed by one or more processors. In otherimplementations, each of the perception system 210, the predictionsystem 212, the motion planning system 214, and the vehicle controller216 includes one or more sets of computer-executable instructions thatare stored in a tangible computer-readable storage medium such as RAMhard disk or optical or magnetic media.

FIG. 3 depicts a block diagram of a more particular features associatedwith an example perception system 210 according to example embodimentsof the present disclosure. As discussed in regard to FIG. 2, a vehiclecomputing system 206 can include a perception system 210 that canidentify one or more objects that are proximate to an autonomous vehicle202. In some embodiments, the perception system 210 can includesegmentation component 306, object associations component 308, trackingcomponent 310, tracked objects component 312, and classificationcomponent 314. The perception system 210 can receive sensor data 302(e.g., from one or more sensor(s) 204 of the autonomous vehicle 202) andmap data 304 as input. The perception system 210 can use the sensor data302 and the map data 304 in determining objects within the surroundingenvironment of the autonomous vehicle 202. In some embodiments, theperception system 210 iteratively processes the sensor data 302 todetect, track, and classify objects identified within the sensor data302. In some examples, the map data 304 can help localize the sensordata to positional locations within a map data or other referencesystem.

Within the perception system 210, the segmentation component 306 canprocess the received sensor data 302 and map data 304 to determinepotential objects within the surrounding environment, for example usingone or more object detection systems. The object associations component308 can receive data about the determined objects and analyze priorobject instance data to determine a most likely association of eachdetermined object with a prior object instance, or in some cases,determine if the potential object is a new object instance. The trackingcomponent 310 can determine the current state of each object instance,for example, in terms of its current position, velocity, acceleration,heading, orientation, uncertainties, and/or the like. The trackedobjects component 312 can receive data regarding the object instancesand their associated state data and determine object instances to betracked by the perception system 210. The classification component 314can receive the data from tracked objects component 312 and classifyeach of the object instances. For example, classification component 314can classify a tracked object as an object from a predetermined set ofobjects (e.g., a vehicle, bicycle, pedestrian, etc.). The perceptionsystem 210 can provide the object and state data for use by variousother systems within the vehicle computing system 206, such as theprediction system 212 of FIG. 2.

FIG. 4 depicts a block diagram of a camera system according to exampleembodiments of the present disclosure. In particular, FIG. 4 depicts anexample embodiment of camera(s) 226 of a sensor system, such as sensorsystem including sensors 204 of FIG. 2, whereby camera(s) 226 cangenerate image data for use by a vehicle computing system in anautonomous vehicle, such as vehicle computing system 206 of FIG. 2, asdiscussed above. In some implementations, camera(s) 226 include aplurality of camera devices (e.g., image capture devices), such ascamera 402, camera 403, and camera 405. Although only the components ofcamera 402 are discussed herein in further detail, it should beappreciated that cameras 2, . . . , N (e.g., camera 403 and camera 405)can include similar components as camera 402. In some implementations,the autonomous vehicle sensor system, such as sensors 204 of FIG. 2, mayinclude at least four cameras, at least five cameras, at least sixcameras, or more or less cameras depending on the desired fields ofview.

Camera 402 can include a shutter 410, one or more lenses 412, one ormore filters 414, and an image sensor 416. Camera 402 can also haveadditional conventional camera components not illustrated in FIG. 4 aswould be understood by one of ordinary skill in the art. When shutter410 of camera 402 is controlled to an open position, incoming lightpasses through lens(es) 412 and filter(s) 414 before reaching imagesensor 416. Lens(es) 412 can be positioned before, between and/or aftershutter 410 to focus images captured by camera 402. Camera 402 canobtain raw image capture data in accordance with a variety of shutterexposure protocols (e.g., a global shutter exposure protocol or arolling shutter exposure protocol) by which a shutter is controlled toexpose image sensor 416 to incoming light. Filter(s) 414 can include,for example, an infrared (IR) filter, a neutral density (NR) filter, anultraviolet (UV) filter, a color filter array, or other filter type.

In some examples, the image sensor 416 can be a charge-coupled device(CCD) sensor or a complementary metal-oxide-semiconductor (CMOS) sensor,although other cameras can also be employed. Image sensor 416 caninclude an array of sensor elements corresponding to unique image pixelsthat are configured to detect incoming light provided incident to asurface of image sensor 416. Each sensor element within image sensor 416can detect incoming light by detecting the amount of light that fallsthereon and converting the received amount of light into a correspondingelectric signal. The more light detected at each pixel, the stronger theelectric signal generated by the sensor element corresponding to thatpixel. In some examples, each sensor element within image sensor 416 caninclude a photodiode and an amplifier along with additional integratedcircuit components configured to generate the electric signalrepresentative of an amount of captured light at each camera element.The electric signals detected at image sensor 416 provide raw imagecapture data at a plurality of pixels, each pixel corresponding to acorresponding sensor element within image sensor 416. Camera 402 can beconfigured to capture successive full image frames of raw image capturedata in successive increments of time.

As illustrated in FIG. 4, camera 402 also can include one or more imageprocessing devices (e.g., image processors) 418 coupled to image sensor416. In some examples, the one or more image processors 418 can includea field-programmable gate array (FPGA) device 420 provided within thecamera 402. In some implementations, FPGA device 420 can correspond toor otherwise include one or more aspects described relative to FPGAdevice 100 of FIG. 1.

FPGA device 420 can include a plurality of programmable logic blocks andinterconnectors 422. Specific configurations of the plurality ofprogrammable logic blocks and interconnectors 422 can be selectivelycontrolled to process raw image capture data received from image sensor416. One or more image data links can be provided to couple the one ormore image processors 418 to image sensor 416. In some examples, eachimage data link can be a high speed data link that can relay relativelylarge amounts of image data while consuming a relatively low amount ofpower. In some examples, image data link(s) can operate using differentsignaling protocols, including but not limited to a Low-VoltageDifferential Signaling (LVDS) protocol, a lower voltage sub-LVDSprotocol, a Camera Serial Interface (CSI) protocol using D-PHY and/orM-PHY physical layers, or other suitable protocols and interface layers.

The one or more image processors 418 can include one or moreprocessor(s) 423 along with one or more memory device(s) 424 that cancollectively function as respective computing devices. The one or moreprocessor(s) 423 can be any suitable processing device such as amicroprocessor, microcontroller, integrated circuit, an applicationspecific integrated circuit (ASIC), a digital signal processor (DSP), afield-programmable gate array (FPGA), logic device, one or more centralprocessing units (CPUs), processing units performing other specializedcalculations, etc. The one or more processor(s) 423 can be a singleprocessor or a plurality of processors that are operatively and/orselectively connected.

The one or more memory device(s) 424 can include one or morenon-transitory computer-readable storage media, such as RAM, ROM,EEPROM, EPROM, flash memory devices, magnetic disks, etc., and/orcombinations thereof. The one or more memory device(s) 424 can storeinformation that can be accessed by the one or more processor(s) 423.For instance, the one or more memory device(s) 424 can includecomputer-readable instructions 426 that can be executed by the one ormore processor(s) 423. The instructions 426 can be software written inany suitable programming language, firmware implemented with variouscontrollable logic devices, and/or can be implemented in hardware.Additionally, and/or alternatively, the instructions 426 can be executedin logically and/or virtually separate threads on processor(s) 423. Theinstructions 426 can be any set of instructions that when executed bythe one or more processor(s) 423 cause the one or more processor(s) 423to perform operations.

The one or more memory device(s) 424 can store data 428 that can beretrieved, manipulated, created, and/or stored by the one or moreprocessor(s) 423. The data 428 can include, for instance, raw imagecapture data, digital image outputs, or other image-related data orparameters. The data 428 can be stored in one or more database(s). Theone or more database(s) can be split up so that they can be provided inmultiple locations.

Camera 402 can include a communication interface 434 used to communicatewith one or more other component(s) of a sensor system or other systemsof an autonomous vehicle, for example, a vehicle computing system suchas vehicle computing system 206 of FIG. 2. The communication interface434 can include any suitable components for interfacing with one or morecommunication channels, including for example, transmitters, receivers,ports, controllers, antennas, or other suitable hardware and/orsoftware. A communication channel can be any type of communicationchannel, such one or more data bus(es) (e.g., controller area network(CAN)), an on-board diagnostics connector (e.g., OBD-II) and/or acombination of wired and/or wireless communication links for sendingand/or receiving data, messages, signals, etc. among devices/systems. Acommunication channel can additionally or alternatively include one ormore networks, such as a local area network (e.g. intranet), wide areanetwork (e.g. Internet), wireless LAN network (e.g., via Wi-Fi),cellular network, a SATCOM network, VHF network, a HF network, a WiMAXbased network, and/or any other suitable communications network (orcombination thereof) for transmitting data to and/or from the camera 402and/or other local autonomous vehicle systems or associated server-basedprocessing or control systems located remotely from an autonomousvehicle. The communication channel can include a direct connectionbetween one or more components. In general, communication usingcommunication channels and/or among one or more component(s) can becarried via communication interface 434 using any type of wired and/orwireless connection, using a variety of communication protocols (e.g.TCP/IP, HTTP, SMTP, FTP), encodings or formats (e.g. HTML, XML), and/orprotection schemes (e.g. VPN, secure HTTP, SSL).

Camera 402 also can include one or more input devices 430 and/or one ormore output devices 432. An input device 430 can include, for example,devices for receiving information from a user, such as a touch screen,touch pad, mouse, data entry keys, speakers, a microphone suitable forvoice recognition, etc. An input device 430 can be used, for example, bya user or accessible computing device to select controllable inputs foroperation of the camera 402 (e.g., shutter, ISO, white balance, focus,exposure, etc.) and or control of one or more parameters. An outputdevice 432 can be used, for example, to provide digital image outputs toa vehicle operator. For example, an output device 432 can include adisplay device (e.g., display screen, CRT, LCD), which can includehardware for displaying an image or other communication to a user.Additionally, and/or alternatively, output device(s) can include anaudio output device (e.g., speaker) and/or device for providing hapticfeedback (e.g., vibration).

FIG. 5 depicts a block diagram of an example computing system 500according to example embodiments of the present disclosure. The examplecomputing system 500 can include a vehicle computing system (e.g.,vehicle computing system 206 of FIG. 2) and a remote computing system530 that are communicatively coupled over a network 580. Remotecomputing system 530 can include one or more remote computing device(s)that are remote from the autonomous vehicle 202. The remote computingsystem 530 can be associated with a central operations system and/or anentity associated with the autonomous vehicle 202 such as, for example,a vehicle owner, vehicle manager, fleet operator, service provider, etc.

In some implementations, the vehicle computing system 206 can performautonomous vehicle motion planning including object detection, tracking,and/or classification (e.g., making object class predictions and objectlocation/orientation estimations as described herein). In someimplementations, the vehicle computing system 206 can be included in anautonomous vehicle. For example, the vehicle computing system 206 can beon-board the autonomous vehicle. In other implementations, the vehiclecomputing system 206 is not located on-board the autonomous vehicle. Forexample, the vehicle computing system 206 can operate offline to performobject detection including making object class predictions and objectlocation/orientation estimations. The vehicle computing system 206 caninclude one or more distinct physical computing devices.

The vehicle computing system 206 can include one or more computingdevices embodied by one or more processors 512 and a memory 514. The oneor more processors 512 can be any suitable processing device (e.g., aprocessor core, a microprocessor, an ASIC, a FPGA, a controller, amicrocontroller, etc.) and can be one processor or a plurality ofprocessors that are operatively connected. The memory 514 can includeone or more non-transitory computer-readable storage media, such as RAM,ROM, EEPROM, EPROM, one or more memory devices, flash memory devices,etc., and combinations thereof.

The memory 514 can store information that can be accessed by the one ormore processors 512. For instance, the memory 514 (e.g., one or morenon-transitory computer-readable storage mediums, memory devices) canstore data 516 that can be obtained, received, accessed, written,manipulated, created, and/or stored. The data 516 can include, forinstance, ranging data obtained by LIDAR system 222 and/or RADAR system224, image data obtained by camera(s) 226, data identifying detectedand/or classified objects including current object states and predictedobject locations and/or trajectories, motion plans, classificationmodels, rules, etc. as described herein. In some implementations, thevehicle computing system 206 can obtain data from one or more memorydevice(s) that are remote from the vehicle computing system 206.

The memory 514 can also store computer-readable instructions 518 thatcan be executed by the one or more processors 512. The instructions 518can be software written in any suitable programming language or can beimplemented in hardware. Additionally, or alternatively, theinstructions 518 can be executed in logically and/or virtually separatethreads on processor(s) 512.

For example, the memory 514 can store instructions 518 that whenexecuted by the one or more processors 512 cause the one or moreprocessors 512 to perform any of the operations and/or functionsdescribed herein, including, for example, operations 702-714 of FIG. 11.

In some implementations, the vehicle computing system 206 can furtherinclude a positioning system 508. The positioning system 508 candetermine a current position of the autonomous vehicle 202. Thepositioning system 508 can be any device or circuitry for analyzing theposition of the autonomous vehicle 202. For example, the positioningsystem 508 can determine position by using one or more of inertialsensors, a satellite positioning system, based on IP address, by usingtriangulation and/or proximity to network access points or other networkcomponents (e.g., cellular towers, WiFi access points, etc.) and/orother suitable techniques. The position of the autonomous vehicle 202can be used by various systems of the vehicle computing system 206.

According to an aspect of the present disclosure, the vehicle computingsystem 206 can store or include one or more classification models 510.As examples, the classification model(s) 510 can be or can otherwiseinclude various models trained by supervised learning and/or machinelearning such as, for example, classification model 130 of FIG. 1.Classification model 510 can include one or more neural networks (e.g.,deep neural networks), support vector machines, decision trees, ensemblemodels, k-nearest neighbors models, Bayesian networks, or other types ofmodels including linear models and/or non-linear models. Example neuralnetworks include feed-forward neural networks, convolutional neuralnetworks, recurrent neural networks (e.g., long short-term memoryrecurrent neural networks), or other forms of neural networks.

In some implementations, the vehicle computing system 206 can receivethe one or more classification models 510 from the remote computingsystem 530 over network 580 and can store the one or more classificationmodels 910 in the memory 514. The vehicle computing system 206 can thenuse or otherwise implement the one or more classification models 510(e.g., by processor(s) 512). In particular, the vehicle computing system206 can implement the classification model(s) 510 to perform objectdetection including making object class predictions. For example, insome implementations, the vehicle computing system 206 can employ theclassification model(s) 510 by inputting one or more image regions intothe classification model(s) 510 and receiving an output of theclassification model 510 including a determination of whether the imageregion does or does not include a detected object, as well as anoptional classification of detected objects and/or confidence scoreindicating the likelihood of accuracy for a detection determinationand/or object class prediction.

The remote computing system 530 can include one or more computingdevices embodied by one or more processors 532 and a memory 534. The oneor more processors 532 can be any suitable processing device (e.g., aprocessor core, a microprocessor, an ASIC, a FPGA, a controller, amicrocontroller, etc.) and can be one processor or a plurality ofprocessors that are operatively connected. The memory 534 can includeone or more non-transitory computer-readable storage media, such as RAM,ROM, EEPROM, EPROM, one or more memory devices, flash memory devices,etc., and combinations thereof.

The memory 534 can store information that can be accessed by the one ormore processors 532. For instance, the memory 534 (e.g., one or morenon-transitory computer-readable storage mediums, memory devices) canstore data 536 that can be obtained, received, accessed, written,manipulated, created, and/or stored. The data 536 can include, forinstance, ranging data, image data, data identifying detected and/orclassified objects including current object states and predicted objectlocations and/or trajectories, motion plans, machine-learned models,rules, etc. as described herein. In some implementations, the remotecomputing system 530 can obtain data from one or more memory device(s)that are remote from the remote computing system 530.

The memory 534 can also store computer-readable instructions 538 thatcan be executed by the one or more processors 532. The instructions 538can be software written in any suitable programming language or can beimplemented in hardware. Additionally, or alternatively, theinstructions 538 can be executed in logically and/or virtually separatethreads on processor(s) 532.

For example, the memory 534 can store instructions 538 that whenexecuted by the one or more processors 532 cause the one or moreprocessors 532 to perform any of the operations and/or functionsdescribed herein, including, for example, operations 702-714 of FIG. 11.

In some implementations, the remote computing system 530 includes one ormore server computing devices. If the remote computing system 530includes multiple server computing devices, such server computingdevices can operate according to various computing architectures,including, for example, sequential computing architectures, parallelcomputing architectures, or some combination thereof.

In addition or alternatively to the classification model(s) 510 at thevehicle computing system 206, the remote computing system 530 caninclude one or more classification models 540. As examples, theclassification model(s) 540 can be or can otherwise include variousmodel(s) trained by supervised learning and/or machine learning such as,for example, neural networks (e.g., deep neural networks), supportvector machines, decision trees, ensemble models, k-nearest neighborsmodels, Bayesian networks, or other types of models including linearmodels and/or non-linear models. Example neural networks includefeed-forward neural networks, convolutional neural networks, recurrentneural networks (e.g., long short-term memory recurrent neuralnetworks), or other forms of neural networks.

As an example, the remote computing system 530 can communicate with thevehicle computing system 206 according to a client-server relationship.For example, the remote computing system 530 can implement theclassification model(s) 540 to provide a web service to the vehiclecomputing system 206. For example, the web service can provide anautonomous vehicle motion planning service.

Thus, classification model(s) 510 can be located and used at the vehiclecomputing system 206 and/or classification model(s) 540 can be locatedand used at the remote computing system 530.

In some implementations, the remote computing system 530 and/or thevehicle computing system 206 can train the classification model(s) 510and/or 540 through use of a model trainer 560. The model trainer 560 cantrain the classification model(s) 510 and/or 540 using one or moretraining or learning algorithms. One example training technique isbackwards propagation of errors. In some implementations, the modeltrainer 560 can perform supervised training techniques using a set oflabeled training data. In other implementations, the model trainer 560can perform unsupervised training techniques using a set of unlabeledtraining data. The model trainer 560 can perform a number ofgeneralization techniques to improve the generalization capability ofthe models being trained. Generalization techniques include weightdecays, dropouts, pruning, or other techniques.

In particular, the model trainer 560 can train a classification model510 or 540 based on a set of training data 562. The training data 562can include, for example, a plurality of sets of ground truth data, eachset of ground truth data including a first portion and a second portion.The first portion of ground truth data can include an example set of oneor more image regions, while the second portion of ground truth data cancorrespond to a class prediction (e.g., an indication that an imageregion includes or does not include one or more classes of objects) thatis manually and/or automatically labeled as correct or incorrect.

The model trainer 560 can train a classification model 510 or 540, forexample, by using one or more sets of ground truth data in the set oftraining data 562. For each set of ground truth data including a firstportion (e.g., an image region) and second portion (e.g., a classprediction), model trainer 560 can: provide the first portion as inputinto the classification model 510 or 540; receive at least one classprediction as an output of the classification model 510 or 540; andevaluate an objective function that describes a difference between theat least one class prediction received as an output of theclassification model(s) 510 or 540 and the second portion of the set ofground truth data. The model trainer 560 can train the classificationmodel(s) 510 or 540 based at least in part on the objective function. Asone example, in some implementations, the objective function can bebackpropagated through a machine-learned classification model 510 or 540to train the classification model 510 or 540. In such fashion, theclassification model(s) 510 and/or 540 can be trained to provide acorrect class prediction on the receipt of one or more image regionsgenerated camera image data. The model trainer 560 can be implemented inhardware, firmware, and/or software controlling one or more processors.

The vehicle computing system 206 can also include a network interface524 used to communicate with one or more systems or devices, includingsystems or devices that are remotely located from the vehicle computingsystem 206. The network interface 524 can include any circuits,components, software, etc. for communicating with one or more networks(e.g., 580). In some implementations, the network interface 524 caninclude, for example, one or more of a communications controller,receiver, transceiver, transmitter, port, conductors, software, and/orhardware for communicating data. Similarly, the remote computing system530 can include a network interface 564.

The network(s) 580 can be any type of network or combination of networksthat allows for communication between devices. In some embodiments, thenetwork(s) can include one or more of a local area network, wide areanetwork, the Internet, secure network, cellular network, mesh network,peer-to-peer communication link, and/or some combination thereof and caninclude any number of wired or wireless links. Communication over thenetwork(s) 580 can be accomplished, for instance, via a networkinterface using any type of protocol, protection scheme, encoding,format, packaging, etc.

FIG. 5 illustrates one example computing system 500 that can be used toimplement the present disclosure. Other computing systems can be used aswell. For example, in some implementations, the vehicle computing system206 can include the model trainer 560 and the training data 562. In suchimplementations, the classification model(s) 510 can be both trained andused locally at the vehicle computing system 206. As another example, insome implementations, the vehicle computing system 206 is not connectedto other computing systems.

In addition, components illustrated and/or discussed as being includedin one of the computing systems 206 or 930 can instead be included inanother of the computing systems 206 or 930. Such configurations can beimplemented without deviating from the scope of the present disclosure.The use of computer-based systems allows for a great variety of possibleconfigurations, combinations, and divisions of tasks and functionalitybetween and among components. Computer-implemented operations can beperformed on a single component or across multiple components.Computer-implemented tasks and/or operations can be performedsequentially or in parallel. Data and instructions can be stored in asingle memory device or across multiple memory devices.

FIG. 6 depicts an example multi-scale image pyramid 600 according toexample embodiments of the present disclosure. For example, amulti-scale image pyramid 600 can include multiple image samples (e.g.,image samples 601-613) that are created by resizing image data (e.g.,image data 102) into multiple image samples having different samplingratios. Resizing to create a multi-scale image pyramid can beimplemented, for example, by resizing component 117 of FPGA device 100in FIG. 1. In some implementations, for example, image resizing caninclude downsampling the image data 102 into multiple image samplesforming the multi-scale image pyramid 600. The multi-scale image pyramid600 can include image data that is translated into multiple imagesamples 601-613, each having a different scaling factor. In someimplementations, the multi-scale image pyramid 600 can be characterizedby a number of octaves (e.g., powers of two) and a number of scales peroctave. Although FIG. 6 depicts multi-scale image pyramid 600 asincluding 13 different image samples, it should be appreciated that anynumber of image samples can be generated in accordance with embodimentsof the disclosed technology. In some implementations, for example, amulti-scale image pyramid is generated having 3 octaves and 3 scales fora total of 2³*3=24 scales.

FIGS. 7-10 depict exemplary aspects of sliding window image analysisaccording to example embodiments of the present disclosure. For example,FIGS. 7-10 depict successive iterations 640, 650, 660 and 670 ofanalyzing an example image sample 642 using a sliding window 644 havinga fixed predetermined size. Image sample 642 can correspond, forexample, to one of the image samples created when generating amulti-scale image pyramid such as depicted in FIG. 6.

In first iteration 640 of FIG. 7, sliding window 644 is positioned at afirst position 646 within image sample 642. In some implementations,first position 646 can correspond to a start position for analyzingsuccessive patches within the image sample 642. Although first position646 is depicted in the upper left corner of image sample 642, it shouldbe appreciated that a start position (e.g., first position 646) cancorrespond to one of the other corners of image sample 642 and/oranother predetermined location within image sample 642 including apredetermined location relative to a subset of each image sample 642. Animage patch 647 can be identified within sliding window 644 at firstposition 646 and provided as an input to a classification model 648.Classification model 648 can correspond, for example, to classificationmodel 130 of FIG. 1 or classification model 510 or 540 of FIG. 5. Theclassification model 648 depicted in FIGS. 7-10 can have been trained tooutput a pedestrian classification prediction that determines whetherimage patch 647 includes or does not include a pedestrian. When imagepatch 647 is provided as input to classification model 648, a “NO”output 649 can be received indicating that image patch 647 does notinclude a pedestrian. Although FIGS. 7-10 depict an exampleclassification prediction for pedestrians, other classifications canadditionally or alternatively be determined.

In second iteration 650 of FIG. 8, sliding window 644 is positioned at asecond position 656 within image sample 642. In some implementations,second position 656 can correspond to a position translated in a givendirection relative to a start position (e.g., first position 646 of FIG.1). For instance, second position 656 corresponds to a positiontranslated horizontally relative to first position 646. It should beappreciated that multiple positions of sliding window 644 can beimplemented between the first position 646 of FIG. 7 and the secondposition 656 of FIG. 8. As such, although the position of sliding window644 in FIGS. 7 and 8 are described as a first position 646 and secondposition 656, the first and second positions 646, 656 are notnecessarily consecutive.

Referring still to FIG. 8, an image patch 657 can be identified withinsliding window 644 at second position 656 and provided as an input toclassification model 648. When image patch 657 is provided as input toclassification model 648, a “NO” output 659 can be received indicatingthat image patch 657 does not include a pedestrian. Successive imagepatches between image patch 647 and image patch 657 as sliding window644 transitions from the first position 646 depicted in FIG. 7 to thesecond position 656 depicted in FIG. 8 can also be provided as input toclassification model 648, with corresponding outputs received therefrom.

In third iteration 660 of FIG. 9, sliding window 644 is positioned at athird position 666 within image sample 642. It should be appreciatedthat multiple positions of sliding window 644 can be implemented betweenthe second position 656 of FIG. 8 and the third position 666 of FIG. 9.As such, although the position of sliding window 644 in FIGS. 8 and 9are described as a second position 656 and third position 666, thesecond and third positions 656, 666 are not necessarily consecutive. Animage patch 667 can be identified within sliding window 644 at thirdposition 666 and provided as an input to classification model 648. Whenimage patch 667 is provided as input to classification model 648, a“YES” output 669 can be received indicating that image patch 667 doesinclude a pedestrian. Successive image patches between image patch 657and image patch 667 as sliding window 644 transitions from the secondposition 656 depicted in FIG. 8 to the third position 666 depicted inFIG. 9 can also be provided as input to classification model 648, withcorresponding outputs received therefrom.

In fourth iteration 670 of FIG. 10, sliding window 644 is positioned ata fourth position 676 within image sample 642. It should be appreciatedthat multiple positions of sliding window 644 can be implemented betweenthe third position 666 of FIG. 9 and the fourth position 676 of FIG. 10.As such, although the position of sliding window 644 in FIGS. 9 and 10are described as a third position 666 and fourth position 676, the thirdand fourth positions 666, 676 are not necessarily consecutive. An imagepatch 677 can be identified within sliding window 644 at fourth position676 and provided as an input to classification model 648. In addition,successive image patches between image patch 667 and image patch 677 assliding window 644 transitions from the third position 666 depicted inFIG. 9 to the fourth position 676 depicted in FIG. 10 can also beprovided as input to classification model 648, with correspondingoutputs received therefrom.

Referring still to FIG. 10, when image patch 677 is provided as input toclassification model 648, a “NO” output 679 can be received indicatingthat image patch 677 does not include a pedestrian. Although image patch677 includes a portion of a pedestrian (e.g., a leg), the pedestrian maynot be recognized by classification model 648 until an image patchcontaining a larger portion or entirety of the pedestrian is provided asinput to classification model 648. This is why multiple image sampleshaving different scales are analyzed using a sliding window 644 of fixedsize. In this manner, objects only partially captured within slidingwindow 644 in some image samples can be fully captured within slidingwindow 644 in one or more other image samples.

FIG. 11 depicts a flow chart diagram of an example method 700 ofdetecting objects of interest according to example embodiments of thepresent disclosure. One or more portion(s) of the method 700 can beimplemented by one or more programmable circuit devices, such as FPGAdevice 100 of FIG. 1, or FPGA device 420 of FIG. 4. Moreover, one ormore portion(s) of the method 700 can be implemented as an algorithm onthe hardware components of the device(s) described herein (e.g., as inFIGS. 1-5).

FIG. 11 depicts elements performed in a particular order for purposes ofillustration and discussion. Those of ordinary skill in the art, usingthe disclosures provided herein, will understand that the elements ofany of the methods discussed herein can be adapted, rearranged,expanded, omitted, combined, and/or modified in various ways withoutdeviating from the scope of the present disclosure. For example, method700 can additionally or alternatively include one or more functionsimplemented by FPGA device 100 of FIG. 1, including but not limited tobit conversion, de-Bayering, gamma correction, color space conversion,rectification, anti-aliasing, resizing, Sobel filtering, angle binning,convolution filtering, pooling, and classification.

At (702), method 700 can include receiving, by one or more programmablecircuit devices, image data from one or more cameras. The image datareceived at (702) can correspond, for example, to image data 102described with reference to FIG. 1 or raw image capture data receivedfrom one or more cameras (e.g., camera(s) 226 of FIG. 2 or cameras 402,403, 405 of FIG. 4).

At (704), method 700 can include generating, by the one or moreprogrammable circuit devices, a multi-scale image pyramid of multipleimage samples having different scaling factors. Generating a multi-scaleimage pyramid at (704) can be implemented, for example, by the resizingcomponent 117 of FPGA device 100, such as illustrated in and describedwith reference to FIG. 1. An example image pyramid of multiple imagesamples as generated at (704) is depicted in FIG. 6.

At (706), method 700 can include analyzing, by the one or moreprogrammable circuit devices, successive image patches within each ofthe multiple image samples using a sliding window of fixed size. At(708), method 700 can include pooling, by the one or more programmablecircuit devices, image patches associated by like features into imageregions within each of the multiple image samples. Analyzing successiveimage patches within each of the multiple image samples at (706) andpooling image patches associated by like features into image regions at(708) can be implemented, for example, by the pooling component 124 ofFPGA device 100, such as illustrated and described with reference toFIG. 1.

At (710), method 700 can include accessing, by the one or moreprogrammable circuit devices, a classification model that classifiesimage regions as including or not including detected objects. In someimplementations, the classification model accessed at (710) can havebeen trained to receive one or more image regions and in response toreceipt of the one or more image regions provide a class predictionoutput. In some implementations, the classification model accessed at(710) can correspond, for example, to classification model 130 of FIG.1, classification model 510 of FIG. 5 or classification model 540 ofFIG. 5.

At (712), method 700 can include providing, by the one or moreprogrammable circuit devices, the image regions from (708) as input tothe classification model accessed at (710). In some implementations,multiple image regions can be provided as an input vector to theclassification model accessed at (710). In some implementations,multiple image regions or vectors of image regions can be provided at(712) to multiple instances of a classification model such that parallelclassifications can be made at or near a same point in time. In someimplementations, one or more image regions can be provided at (712) toone or more instances of a classification model accessed at (710) in aniterative fashion such that outputs from the classification model can beiteratively produced/received at (714).

At (714), method 700 can include producing/receiving, by the one or moreprogrammable circuit devices, an output of the classification modelcorresponding to detected objects of interest within the image data. Forexample, in some implementations, an output of the classification modelreceived at (714) can include a class prediction output. A classprediction output can correspond, for example, to a determination ofwhether an image region includes or does not include one or more classesof objects. For example, the class prediction output can correspond to aclassification selected from a predetermined set of classifications(e.g., pedestrian, vehicle, bicycle, no object). In someimplementations, the class prediction output can also include aprobability score associated with each classification indicating alikelihood that the determined classification is accurate.

While the present subject matter has been described in detail withrespect to various specific example embodiments thereof, each example isprovided by way of explanation, not limitation of the disclosure. Thoseskilled in the art, upon attaining an understanding of the foregoing,can readily produce alterations to, variations of, and equivalents tosuch embodiments. Accordingly, the subject disclosure does not precludeinclusion of such modifications, variations and/or additions to thepresent subject matter as would be readily apparent to one of ordinaryskill in the art. For instance, features illustrated or described aspart of one embodiment can be used with another embodiment to yield astill further embodiment. Thus, it is intended that the presentdisclosure cover such alterations, variations, and equivalents.

What is claimed is:
 1. An image processing system, comprising: one ormore cameras configured to obtain image data; one or more memory devicesconfigured to store a classification model that classifies imagefeatures within the image data as including or not including detectedobjects; and a field programmable gate array (FPGA) device coupled tothe one or more cameras, the FPGA device configured to implement one ormore image processing pipelines for image transformation and objectdetection; the one or more image processing pipelines including aplurality of logic blocks and interconnectors programmed to: generate amulti-scale image pyramid of multiple image samples having differentscaling factors; identify and aggregate features within one or more ofthe multiple image samples having different scaling factors; access theclassification model stored in the one or more memory devices; providethe features within the one or more of the multiple image samples asinput to the classification model; and produce an output indicative ofobjects detected within the image data; wherein the features identifiedand aggregated within the one or more of the multiple image samplescomprise edge portions, and wherein the one or more image processingpipelines further include a plurality of logic blocks andinterconnectors that are programmed to determine an angle classificationfor each of the identified edge portions, and to assign the edge portionto one of a plurality of different bins depending on the angleclassification for that edge portion.
 2. The image processing system ofclaim 1, wherein the one or more image processing pipelines furtherinclude a plurality of logic blocks and interconnectors that areprogrammed to determine a histogram descriptive of the plurality ofdifferent bins.
 3. The image processing system of claim 2, wherein thehistogram comprises a histogram of oriented gradients for the identifiededge portions.
 4. The image processing system of claim 1, wherein theplurality of different bins are defined to have different sizes based onan amount of image data in each image sample such that bin sizes aresmaller for image samples having a greater amount of image data.
 5. Theimage processing system of claim 1, wherein the one or more imageprocessing pipelines include a plurality of logic blocks andinterconnectors programmed to generate one or more channel images fromthe image data, each channel image corresponding to a feature map thatmaps a patch of one or more input pixels from the image data to anoutput pixel within the channel image.
 6. The image processing system ofclaim 1, wherein the one or more image processing pipelines furtherinclude a plurality of logic blocks and interconnectors designed toconvert intermediate stages of the image data from the one or morecameras from a floating point representation to fixed pointinteger-based representation.
 7. The image processing system of claim 1,wherein the one or more image processing pipelines further include aplurality of logic blocks and interconnectors programmed to convert theimage data from the one or more cameras into a multi-parameterrepresentation including values corresponding to an image hue parameter,an image saturation parameter, and an image greyscale parameter.
 8. Theimage processing system of claim 1, wherein the one or more imageprocessing pipelines further include a plurality of logic blocks andinterconnectors programmed to convert the image data from arepresentation having multiple color components to a greyscalerepresentation.
 9. The image processing system of claim 1, wherein theone or more image processing pipelines include a plurality of logicblocks and interconnectors programmed to determine a sliding window offixed size, to analyze successive image patches within each of themultiple image samples using the sliding window of fixed size, and toidentify objects of interest within the successive image patches.
 10. Avehicle control system, comprising: one or more cameras configured toobtain image data within an environment proximate to a vehicle; a fieldprogrammable gate array (FPGA) device coupled to one or more cameras,the FPGA device configured to implement one or more image processingpipelines for image transformation and object detection, the one or moreimage processing pipelines including a plurality of logic blocks andinterconnectors programmed to: generate from the image data amulti-scale image pyramid of multiple image samples having differentscaling factors; identify and aggregate features within one or more ofthe multiple image samples having different scaling factors; and todetect one or more objects of interest within the multiple image samplesbased at least in part on the features, wherein the features identifiedand aggregated within the one or more of the multiple image samplescomprise edge portions, and wherein the second image processing pipelinefor object detection further includes a plurality of logic blocks andinterconnectors that are programmed to determine an angle classificationfor each of the identified edge portions, and to assign the edge portionto one of a plurality of different bins depending on the angleclassification for that edge portion; one or more computing devicesconfigured to receive an output from the FPGA device and to furthercharacterize the objects of interest.
 11. The vehicle control system ofclaim 10, wherein the one or more computing devices are furtherconfigured to control motion of the vehicle based at least in part onthe one or more objects of interest detected within the image data fromthe one or more cameras.
 12. The vehicle control system of claim 10,wherein the one or more image processing pipelines further include aplurality of logic blocks and interconnectors that are programmed todetermine a histogram of oriented gradients descriptive of the pluralityof different bins.
 13. The vehicle control system of claim 10, whereinthe plurality of different bins are defined to have different sizesbased on an amount of image data in each image sample such that binsizes are smaller for image samples having a greater amount of imagedata.
 14. The vehicle control system of claim 10, wherein the one ormore image processing pipelines further include a plurality of logicblocks and interconnectors programmed to convert the image data from theone or more cameras into a multi-parameter representation includingvalues corresponding to an image hue parameter, an image saturationparameter, and an image greyscale parameter.
 15. The vehicle controlsystem of claim 10, wherein the one or more image processing pipelinesfurther include a plurality of logic blocks and interconnectorsprogrammed to determine a sliding window of fixed size, to analyzesuccessive image patches within each of the multiple image samples usingthe sliding window of fixed size, and to identify objects of interestwithin the successive image patches.